阅读说明：本技术 一种生产无缝钢管用燃气式热处理炉 (Gas type heat treatment furnace for producing seamless steel pipes ) 是由 叶志航 叶夏旋 于 2021-08-03 设计创作，主要内容包括：本发明的技术方案是这样实现的：一种生产无缝钢管用燃气式热处理炉,其特征在于：包括炉体,呈圆柱状；第一电机,安装在炉体上端中心处；旋转轴,竖直设置在炉体内部；隔板,设置为三块且周向均匀设置在旋转轴上；所述隔板将炉体内部分为送料腔、预热腔和加热腔,所述炉体上设置有炉门,所述炉门与送料腔连通,该炉门底部与炉体滑动连接；所述炉体内还设置有承料机构,固定在隔板上,用于放置钢管；送料机构,固定在炉门上,用于向承料机构上放置或取出钢管；其中,所述送料机构包括送料板,固定在炉门内侧；吸附铁板,固定于送料板底部；电磁控制组件,用于控制吸附铁板磁力的通断；本发明的有益效果是：进出料安全性高,生产效率高。(The technical scheme of the invention is realized as follows: the utility model provides a production gas formula heat treatment furnace for seamless steel pipe which characterized in that: comprises a furnace body which is cylindrical; the first motor is arranged at the center of the upper end of the furnace body; the rotating shaft is vertically arranged inside the furnace body; the three partition plates are uniformly arranged on the rotating shaft in the circumferential direction; the furnace body is provided with a furnace door which is communicated with the feeding cavity, and the bottom of the furnace door is in sliding connection with the furnace body; the furnace body is also internally provided with a material bearing mechanism which is fixed on the partition plate and used for placing the steel pipe; the feeding mechanism is fixed on the furnace door and used for placing or taking out the steel pipe on the material bearing mechanism; the feeding mechanism comprises a feeding plate and is fixed on the inner side of the furnace door; the adsorption iron plate is fixed at the bottom of the feeding plate; the electromagnetic control assembly is used for controlling the on-off of the magnetic force of the adsorption iron plate; the invention has the beneficial effects that: the feeding and discharging safety is high, and the production efficiency is high.)

1. The utility model provides a production gas formula heat treatment furnace for seamless steel pipe which characterized in that: comprises that

The furnace body is cylindrical;

the first motor is arranged at the center of the upper end of the furnace body;

the rotating shaft is vertically arranged in the furnace body and is controlled by the first motor to rotate;

the three partition plates are uniformly arranged on the rotating shaft in the circumferential direction;

the inner part of the furnace body is divided into a feeding cavity, a preheating cavity and a heating cavity by the partition plates, and each partition plate is hermetically connected with the inner wall of the furnace body; the furnace body is provided with a furnace door, the furnace door is communicated with the feeding cavity, and the bottom of the furnace door is in sliding connection with the furnace body; the furnace body is also internally provided with

The material bearing mechanism is fixed on the partition plate and used for placing the steel pipe;

the feeding mechanism is fixed on the furnace door and used for placing or taking out the steel pipe on the material bearing mechanism;

wherein the feeding mechanism comprises

The feeding plate is fixed on the inner side of the furnace door;

the adsorption iron plate is fixed at the bottom of the feeding plate;

the electromagnetic control assembly is arranged outside the furnace door and used for controlling the on-off of the magnetic force of the adsorption iron plate;

when the furnace door is closed, the feeding plate is positioned above the material bearing mechanism and arranged at intervals with the material bearing mechanism, and the feeding plate is made of insulating materials.

2. A gas-fired heat treatment furnace for producing seamless steel pipes as claimed in claim 1, characterized in that: the material bearing mechanism comprises a plurality of material bearing units which are uniformly arranged along the height direction, and each material bearing unit comprises

The supporting plate is of a fan-shaped structure, and two ends of the supporting plate are fixed on the partition plate;

the material bearing plate is fixed at the upper end of the supporting plate;

the number of the feeding plates corresponds to that of the material bearing units, and when the furnace door is closed, each feeding plate is correspondingly positioned at the upper end of one material bearing unit; and the interval between the adsorption iron plate and the material bearing plate is larger than the diameter of the steel pipe.

3. A gas-fired heat treatment furnace for producing seamless steel pipes as claimed in claim 2, characterized in that: the material bearing plate is characterized in that a plurality of first fixing grooves are formed in the upper end of the material bearing plate, the first fixing grooves are evenly arranged in the circumferential direction of the rotating shaft, second fixing grooves are formed in the lower end of the adsorption iron plate corresponding to the first fixing grooves, and the first fixing grooves and the second fixing grooves are both arc-shaped structures.

4. The gas-fired heat treatment furnace for producing seamless steel pipes according to any one of claims 1 to 3, characterized in that: the heating cavity is internally provided with a plurality of burners, each burner is embedded on the inner wall of the furnace body, the heating cavity is internally provided with a turbulence mechanism, the turbulence mechanism is embedded on the inner wall of the furnace body, and the turbulence mechanism comprises

The second motor is arranged on the outer wall of the furnace body;

the rotating disc is arranged in the heating cavity and is controlled by the second motor to rotate;

the carousel has seted up the vortex groove towards the one side of holding the material mechanism, install the spiral rib in the vortex groove.

5. The gas-fired heat treatment furnace for producing seamless steel pipes according to any one of claims 1 to 3, characterized in that: be provided with heat preservation mechanism in heating chamber department on the furnace body, heat preservation mechanism includes

The heat insulation channel is arranged on the inner side wall of the furnace body and wraps the heating cavity;

a pressure control mechanism;

wherein, set up the gas vent that communicates heating chamber and heat preservation passageway on the furnace body, accuse pressure mechanism sets up on the gas vent, accuse pressure mechanism includes

The sealing plug can open and close the exhaust port;

and two ends of the spring are respectively fixed in the sealing plug and the heat preservation channel.

6. A gas-fired heat treatment furnace for producing seamless steel pipes as claimed in claim 5, wherein: the partition board comprises

The reinforcing plates are arranged in two blocks;

the asbestos heat insulation layer is arranged between the two reinforcing plates;

a corrosion-resistant layer; the reinforcing plate is arranged at one end of the reinforcing plate far away from the asbestos heat insulation layer;

the corrosion-resistant layer is provided with an adsorption tank, an activated carbon adsorbent is arranged in the adsorption tank, the upper end and the lower end of the partition plate are both provided with sealing layers, and the lower end of the partition plate is also embedded with a sliding block in the sealing layers.

7. A gas-fired heat treatment furnace for producing seamless steel pipes as claimed in claim 5, wherein: the preheating cavity is internally provided with a preheating mechanism which comprises

The gas pipe is communicated with the heat preservation channel and the preheating cavity;

the preheating pipe is positioned in the preheating cavity, embedded on the inner wall of the furnace body and communicated with the gas conveying pipe;

the air nozzle is arranged on the preheating pipe, and the output end of the air nozzle faces the material bearing mechanism;

and the gas transmission pipe is provided with a pressure gauge and an electric control valve.

8. A gas-fired heat treatment furnace for producing seamless steel pipes as claimed in claim 7, wherein: the preheating mechanism also comprises

The fan is embedded on the inner wall of the furnace body;

the heater is arranged on the output end of the fan;

the output end of the fan faces the preheating cavity.

9. A gas-fired heat treatment furnace for producing seamless steel pipes as claimed in claim 3, characterized in that: the furnace door is also provided with a cooling mechanism which comprises

The delivery pump is arranged on the furnace door;

the cold air source is connected with the input end of the delivery pump and used for providing cold air for the delivery pump;

the cooling channel is arranged on the adsorption iron plate;

the cooling pipe is arranged on the output end of the delivery pump and is communicated with the delivery pump and the cooling channel;

and the cooling hole is formed in the adsorption iron plate and communicated with the cooling channel and the lower end of the adsorption iron plate.

10. A gas-fired heat treatment furnace for producing seamless steel pipes as claimed in claim 9, characterized in that: the cooling hole and the second fixing groove are arranged in a staggered mode, and the output end of the cooling hole inclines towards the second fixing groove.

Technical Field

The invention relates to the technical field of steel pipe processing equipment, in particular to a gas type heat treatment furnace for producing seamless steel pipes.

Background

The seamless steel pipe has a hollow section and is used as a pipeline for conveying a large amount of fluid, such as petroleum, natural gas, coal gas, water, certain solid materials and the like; compared with solid steel such as round steel and the like, the seamless steel pipe has lighter weight under the same bending and torsion strength; meanwhile, the seamless steel pipe is also widely used for manufacturing structural parts and mechanical parts, such as a petroleum drill pipe, an automobile transmission shaft, a bicycle frame, a steel scaffold used in building construction and the like, and has the advantages of high material utilization rate, simple manufacturing process and reduced processing working hours; it is because of the special use of seamless steel pipes that they need to be heat treated during their production, which generally includes annealing, normalizing, quenching and tempering.

In prior art, for example, the heat treatment furnace that patent publication No. CN209989426U discloses, it can preheat in the stove, but is the same with the heat treatment furnace of most on the market, and its structure is comparatively complicated, and the business turn over material of steel pipe is comparatively inconvenient, and the manual work is gone on easily by the hot-air scald when advancing to get the material, and needs the manual work to adjust comparatively inconvenient to the atmospheric pressure in the stove, and the higher temperature that is not suitable for subsequent processing of getting of steel pipe taking out at heat treatment simultaneously, has the potential safety hazard.

Disclosure of Invention

In view of the shortcomings of the prior art, the present invention aims to provide a gas heat treatment furnace for producing seamless steel tubes, which is used for solving the technical problems in the background art.

The technical scheme of the invention is realized as follows: the utility model provides a production gas formula heat treatment furnace for seamless steel pipe which characterized in that: comprises a furnace body which is cylindrical; the first motor is arranged at the center of the upper end of the furnace body; the rotating shaft is vertically arranged in the furnace body and is controlled by the first motor to rotate; the three partition plates are uniformly arranged on the rotating shaft in the circumferential direction; the inner part of the furnace body is divided into a feeding cavity, a preheating cavity and a heating cavity by the partition plates, and each partition plate is hermetically connected with the inner wall of the furnace body; the furnace body is provided with a furnace door, the furnace door is communicated with the feeding cavity, and the bottom of the furnace door is in sliding connection with the furnace body; the furnace body is also internally provided with a material bearing mechanism which is fixed on the partition plate and used for placing the steel pipe; the feeding mechanism is fixed on the furnace door and used for placing or taking out the steel pipe on the material bearing mechanism; the feeding mechanism comprises a feeding plate and is fixed on the inner side of the furnace door; the adsorption iron plate is fixed at the bottom of the feeding plate; the electromagnetic control assembly is arranged outside the furnace door and used for controlling the on-off of the magnetic force of the adsorption iron plate; when the furnace door is closed, the feeding plate is positioned above the material bearing mechanism and arranged at intervals with the material bearing mechanism, and the feeding plate is made of insulating materials.

Preferably: the material bearing mechanism comprises a plurality of material bearing units which are uniformly arranged along the height direction, each material bearing unit comprises a supporting plate which is of a fan-shaped structure, and two ends of each material bearing unit are fixed on the partition plate; the material bearing plate is fixed at the upper end of the supporting plate; the number of the feeding plates corresponds to that of the material bearing units, and when the furnace door is closed, each feeding plate is correspondingly positioned at the upper end of one material bearing unit; and the interval between the adsorption iron plate and the material bearing plate is larger than the diameter of the steel pipe.

Preferably: the material bearing plate is characterized in that a plurality of first fixing grooves are formed in the upper end of the material bearing plate, the first fixing grooves are evenly arranged in the circumferential direction of the rotating shaft, second fixing grooves are formed in the lower end of the adsorption iron plate corresponding to the first fixing grooves, and the first fixing grooves and the second fixing grooves are both arc-shaped structures.

Preferably: the heating cavity is internally provided with a plurality of burners, each burner is embedded on the inner wall of the furnace body, the heating cavity is also internally provided with a turbulence mechanism, the turbulence mechanism is embedded on the inner wall of the furnace body, and the turbulence mechanism comprises a second motor and is arranged on the outer wall of the furnace body; the rotating disc is arranged in the heating cavity and is controlled by the second motor to rotate; the carousel has seted up the vortex groove towards the one side of holding the material mechanism, install the spiral rib in the vortex groove.

Preferably: a heat preservation mechanism is arranged at the heating cavity on the furnace body, and the heat preservation mechanism comprises a heat preservation channel which is arranged on the inner side wall of the furnace body and wraps the heating cavity; a pressure control mechanism; the furnace body is provided with an exhaust port communicated with the heating cavity and the heat preservation channel, the pressure control mechanism is arranged on the exhaust port, and the pressure control mechanism comprises a sealing plug and can open and close the exhaust port; and two ends of the spring are respectively fixed in the sealing plug and the heat preservation channel.

Preferably: the partition plate comprises two reinforcing plates; the asbestos heat insulation layer is arranged between the two reinforcing plates; a corrosion-resistant layer; the reinforcing plate is arranged at one end of the reinforcing plate far away from the asbestos heat insulation layer; the corrosion-resistant layer is provided with an adsorption tank, an activated carbon adsorbent is arranged in the adsorption tank, the upper end and the lower end of the partition plate are both provided with sealing layers, and the lower end of the partition plate is also embedded with a sliding block in the sealing layers.

Preferably: a preheating mechanism is arranged in the preheating cavity, and comprises a gas pipe and is communicated with the heat preservation channel and the preheating cavity; the preheating pipe is positioned in the preheating cavity, embedded on the inner wall of the furnace body and communicated with the gas conveying pipe; the air nozzle is arranged on the preheating pipe, and the output end of the air nozzle faces the material bearing mechanism; and the gas transmission pipe is provided with a pressure gauge and an electric control valve.

Preferably: the preheating mechanism also comprises a fan which is embedded on the inner wall of the furnace body; the heater is arranged on the output end of the fan; the output end of the fan faces the preheating cavity.

Preferably: the furnace door is also provided with a cooling mechanism, and the cooling mechanism comprises a delivery pump and is arranged on the furnace door; the cold air source is connected with the input end of the delivery pump and used for providing cold air for the delivery pump; the cooling channel is arranged on the adsorption iron plate; the cooling pipe is arranged on the output end of the delivery pump and is communicated with the delivery pump and the cooling channel; and the cooling hole is formed in the adsorption iron plate and communicated with the cooling channel and the lower end of the adsorption iron plate.

Preferably: the cooling hole and the second fixing groove are arranged in a staggered mode, and the output end of the cooling hole inclines towards the second fixing groove.

The invention has the beneficial effects that:

(1) divide into the furnace body inside into the pay-off chamber, preheat the three cavity of chamber and heating chamber, and carry work through first motor control steel pipe in three cavity, and three cavity can realize synchronous work, handle three each batches of steel pipe simultaneously, rotate to the pay-off chamber and carry out ejection of compact and feeding when first batch of steel pipe heating back need take out and re-feed steel pipe, the steel pipe in the second batch rotates to preheating the chamber from the pay-off chamber and preheats, the steel pipe of third batch gets into the heating chamber from preheating the chamber and heats, reach the purpose of processing and connecting thermal treatment to a plurality of batches of steel pipes simultaneously, production efficiency has been increased substantially.

(2) The feeding mechanism is arranged on the furnace door, the steel pipe is arranged outside the furnace body along with the feeding mechanism during feeding and taking, the steel pipe does not need to enter the high-temperature furnace body during feeding and taking, the safety is high, and workers are not easily scalded; through feeding mechanism's setting, through the absorption that control electromagnetic control assembly control absorption iron plate reached the feeding and got the purpose of material to the steel pipe, realize holistic feeding and ejection of compact through the break-make of magnetic force, it is convenient to pass in and out the material, and the security is high, improves work efficiency.

(3) Through the setting of vortex mechanism, when the steel pipe heating, start the second motor, the second motor drives the carousel and rotates, through the setting of vortex groove and spiral rib, the hot-air that drives the heating intracavity rotates at the heating chamber middle part with the mode of spiral, gaseous abundant and steel pipe contact, with most hot-air gathering at the heating chamber middle part with the mode of spiral simultaneously, the steam that reduces the heating chamber border flows, when making the steel pipe fully heated, it runs off to reduce the heat through the furnace body lateral wall, the stability of steel pipe heating is improved.

(4) Through the setting of heat preservation mechanism, heat intracavity high temperature high pressure, rise along with the atmospheric pressure in the heating chamber, extrude the interior sealing plug of exhaust vent, its pressure of applying for the sealing plug when atmospheric pressure reaches a certain degree is greater than the elasticity of spring and upwards promotes the sealing plug, the hot gas flow enters into the heat preservation passageway through the gas vent this moment, after pressure reduces, the sealing plug moves downwards and closes the gas vent again, when playing automatic control heating intracavity atmospheric pressure, the hot gas flow gets into the heat preservation passageway, form multichannel insulating layer with the furnace body wall, scatter and disappear earlier by the heat in the heat preservation passageway when scattering and disappearing the heat, and the heating chamber can provide hot air to the heat preservation passageway, the heat preservation passageway keeps warm to the heating chamber again, increase substantially the inside heat preservation effect in heating chamber.

(5) Through the arrangement of the preheating mechanism, hot air flow discharged from the heating cavity due to high pressure is conveyed into the preheating pipe from the heat preservation channel through the air conveying pipe, the air nozzle blows the hot air to the steel pipe to preheat the steel pipe, whether the air pressure in the heating cavity is stable or not can be detected through the observation pressure gauge, and the electric control valve can be closed to perform maintenance and detect faults; meanwhile, through the arrangement of the fan and the heater, hot air is formed, and when the hot air exhausted from the heating cavity is not enough for preheating, auxiliary preheating is carried out.

(6) Through the arrangement of the cooling mechanism, when the steel pipe is discharged, the steel pipe is adsorbed by the adsorption iron plate, the conveying pump is started at the same time, cold air is conveyed into the cooling channel of the adsorption iron plate through the cooling pipe, and the cold air is directly blown to the steel pipe to primarily cool the steel pipe during discharging, so that the safety of subsequent material taking and processing is ensured; the preliminary cooling to the steel pipe can be reached when getting the material, improves production efficiency.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a perspective schematic view of an embodiment of the present invention;

FIG. 2 is a schematic top view of an embodiment of the present invention;

FIG. 3 is a schematic view of a first fixing groove according to an embodiment of the present invention;

FIG. 4 is a schematic structural diagram of a turntable according to an embodiment of the present invention;

FIG. 5 is a schematic structural view of a heat retention mechanism in an embodiment of the present invention;

FIG. 6 is an enlarged schematic view at A in FIG. 5;

FIG. 7 is a schematic structural view of a separator according to an embodiment of the present invention;

FIG. 8 is a schematic structural view of a preheating mechanism according to an embodiment of the present invention;

FIG. 9 is a schematic structural diagram of a cooling mechanism according to an embodiment of the present invention;

FIG. 10 is a schematic view of a cooling hole configuration according to an embodiment of the present invention;

the examples in the figure are: the furnace comprises a furnace body 1, a feeding cavity 1a, a preheating cavity 1b, a heating cavity 1c, a furnace door 2, a first motor 3, a rotating shaft 4, a partition plate 5, a material bearing mechanism 6, a feeding mechanism 7, a turbulence mechanism 8, a heat preservation mechanism 9, a preheating mechanism 10 and a cooling mechanism 11;

a 51 reinforcing plate, a 52 asbestos heat-insulating layer, a 53 corrosion-resistant layer, a 54 adsorption tank, a 55 sealing layer and a 56 sliding block;

61 supporting plates, 62 material bearing plates and 63 first fixing grooves;

71 a feeding plate, 72 an adsorption iron plate, 73 an electromagnetic control assembly, 74 a second fixing groove;

81 burners, 82 second motors, 83 turntables, 84 turbulence grooves and 85 spiral ribs;

91 heat preservation channel, 92 air outlet, 93 sealing plug, 94 spring;

101 gas transmission pipe, 102 preheating pipe, 103 gas nozzle, 104 pressure measuring instrument, 105 electric control valve, 106 blower, 107 heater;

111 transfer pump, 112 cold gas source, 113 cooling channel, 114 cooling tube, 115 cooling hole.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

As shown in fig. 1 to 8, the present invention discloses a gas-fired heat treatment furnace for producing seamless steel pipes, which comprises a furnace body 1 having a cylindrical shape in an embodiment of the present invention; the first motor 3 is arranged at the center of the upper end of the furnace body 1; the rotating shaft 4 is vertically arranged in the furnace body 1 and is controlled by the first motor 3 to rotate; the partition plates 5 are arranged in three pieces and are uniformly arranged on the rotating shaft 4 in the circumferential direction; the baffle 5 connects the furnace; the inner part of the furnace body is a feeding cavity 1a, a preheating cavity 1b and a heating cavity 1c, and each partition plate 5 is hermetically connected with the inner wall of the furnace body 1; the furnace body 1 is provided with a furnace door 2, the furnace door 2 is communicated with the feeding cavity 1a, and the bottom of the furnace door 2 is connected with the furnace body 1 in a sliding way; the furnace body 1 is also internally provided with a material bearing mechanism 6 which is fixed on the partition plate 5 and used for placing steel pipes; the feeding mechanism 7 is fixed on the furnace door 2 and used for placing or taking out the steel pipe on the material bearing mechanism 6; wherein, the feeding mechanism 7 comprises a feeding plate 71 which is fixed on the inner side of the furnace door 2; the adsorption iron plate 72 is fixed at the bottom of the feeding plate; the electromagnetic control assembly 73 is arranged outside the furnace door 2 and used for controlling the on-off of the magnetic force of the adsorption iron plate; when the furnace door 2 is closed, the feeding plate is positioned above the material bearing mechanism and arranged at an interval with the material bearing mechanism, the feeding plate is made of insulating materials, and the feeding plate is made of the insulating materials so as to avoid influencing the electromagnetic adsorption work of the adsorption iron plate.

In this embodiment, the material supporting mechanism 6 includes a plurality of material supporting units uniformly arranged along the height direction, each material supporting unit includes a supporting plate 61 in a fan-shaped structure, and two ends of the supporting plate are fixed on the partition plate 5; a material bearing plate 62 fixed on the upper end of the support plate 61; the number of the feeding plates 71 corresponds to that of the material bearing units, and when the furnace door 2 is closed, each feeding plate is correspondingly positioned at the upper end of one material bearing unit; and the interval between the adsorption iron plate and the material bearing plate 62 is larger than the diameter of the steel pipe.

In this embodiment, the material receiving plate is provided at an upper end thereof with a plurality of first fixing grooves 63, each of the first fixing grooves 63 is uniformly arranged around the circumferential direction of the rotating shaft, the lower end of the iron adsorbing plate is provided with a second fixing groove 74 corresponding to the first fixing groove 63, and the first fixing groove and the second fixing groove 74 are both arc-shaped structures.

When feeding, firstly, the furnace door is pulled out in a sliding mode, the feeding plate is located outside the furnace body, then the electromagnetic control assembly is started, so that the adsorption iron plate generates adsorption magnetic force, then the steel pipe to be processed is adsorbed at the lower end of the adsorption iron plate corresponding to the second fixing groove, after the steel pipe at the lower end of each adsorption iron plate is adsorbed and installed, the furnace door is pushed to be closed, the steel pipe enters the feeding cavity, after the furnace door is closed, the steel pipe is located at the upper end of the first fixing groove of the material bearing plate, the electromagnetic control unit is closed, so that the adsorption iron plate loses adsorption force, the steel pipe falls downwards onto the first fixing groove due to self gravity and is supported by the material bearing plate, and feeding is completed;

then, start first motor and drive the rotation axis and rotate, the baffle rotates along with it and carries the steel pipe to preheating the intracavity, preheats by preheating the chamber, and in the pivoted, the steel pipe that the heating was accomplished in the heating intracavity rotates and carries to the pay-off intracavity, carries out to get the material to the steel pipe after the thermal treatment, specifically does: and starting the electromagnetic control assembly to enable the adsorption iron plate to generate adsorbed magnetic force, adsorbing the steel pipe on the material bearing plate to the adsorption iron plate again, then opening and moving out the furnace door, moving out the steel pipe along with the adsorption iron plate, closing the electromagnetic control assembly to enable the adsorption iron plate to lose the magnetic force, and taking the steel pipe by using a tool.

Through the technical scheme, the furnace body is internally provided with the three cavities of the feeding cavity, the preheating cavity and the heating cavity, the steel pipes are controlled to be conveyed in the three cavities through the first motor, the three cavities can realize synchronous work, three batches of steel pipes are processed simultaneously, the steel pipes in the first batch are rotated to the feeding cavity to be discharged and fed when being required to be taken out and fed again after being heated, the steel pipes in the second batch are rotated to the preheating cavity from the feeding cavity to be preheated, the steel pipes in the third batch enter the heating cavity from the preheating cavity to be heated, the aims of simultaneously processing and connecting the steel pipes in multiple batches for heat treatment are fulfilled, and the production efficiency is greatly improved.

Meanwhile, the feeding mechanism is arranged on the furnace door, the steel pipe is arranged outside the furnace body along with the feeding mechanism during feeding and taking, the steel pipe does not need to enter the high-temperature furnace body during feeding and taking, the safety is high, and workers are not easily scalded; through feeding mechanism's setting, through the absorption that control electromagnetic control assembly control absorption iron plate reached the feeding and got the purpose of material to the steel pipe, realize holistic feeding and ejection of compact through the break-make of magnetic force, it is convenient to pass in and out the material, and the security is high, improves work efficiency.

In addition, through the setting of first fixed slot and second fixed slot, be convenient for when adsorbing the feeding, directly adsorb the steel pipe in the second fixed slot, the feeding is convenient, and the range is neat, and the make full use of area reaches the feeding of at utmost, and the steel pipe directly gets into first fixed slot from the second fixed slot during the feeding simultaneously, rolls on the holding plate when avoiding the steel pipe feeding, has guaranteed steel pipe thermal treatment's stability.

In this embodiment, a plurality of burners 81 are arranged in the heating chamber 1c, each burner 81 is embedded on the inner wall of the furnace body 1, a turbulence mechanism 8 is further arranged in the heating chamber 1c, the turbulence mechanism 8 is embedded on the inner wall of the furnace body 1, and the turbulence mechanism comprises a second motor 82 and is installed on the outer wall of the furnace body 1; a rotary plate 83 disposed in the heating chamber 1c and controlled to rotate by the second motor 82; a flow disturbing groove 84 is formed in one side, facing the material bearing mechanism, of the rotary disc 83, and a spiral rib 85 is installed in the flow disturbing groove 84.

Through the technical scheme, through the setting of vortex mechanism, when the steel pipe heating, start the second motor, the second motor drives the carousel and rotates, through the setting of vortex groove and spiral rib, the hot-air that drives the heating intracavity rotates at the heating chamber middle part with the mode of spiral, gaseous abundant and steel pipe contact, with the mode of spiral with most hot-air gathering at the heating chamber middle part simultaneously, reduce the steam flow at heating chamber border, when making the steel pipe fully heated, it runs off to reduce the heat through the furnace body lateral wall, improve the stability of steel pipe heating.

In this embodiment, a heat preservation mechanism 9 is arranged on the heating cavity 1c of the furnace body 1, and the heat preservation mechanism 9 includes a heat preservation channel 91 which is arranged on the inner side wall of the furnace body 1 and wraps the heating cavity 1 c; a pressure control mechanism; wherein, the furnace body 1 is provided with an exhaust port 92 for communicating the heating cavity 1c and the heat preservation channel, the pressure control mechanism is arranged on the exhaust port 92, the pressure control mechanism comprises a sealing plug 93 which can open and close the exhaust port; a spring 94, the two ends of which are fixed in the sealing plug and the insulation channel, respectively.

Through the technical scheme, through the setting of heat preservation mechanism, heat intracavity high temperature high pressure, rise along with the atmospheric pressure in the heating chamber, extrude the interior sealing plug of exhaust vent, its pressure of applying for the sealing plug when atmospheric pressure reaches a certain degree is greater than the elasticity of spring and upwards promotes the sealing plug, the hot gas flow enters into the heat preservation passageway through the exhaust vent this moment, after pressure reduces, the sealing plug moves downwards and recloses the exhaust vent, when playing automatic control heating intracavity air pressure, the hot gas flow gets into the heat preservation passageway, form multichannel insulating layer with the furnace body wall, scatter and disappear by the heat in the heat preservation passageway earlier when scattering and disappearing the heat, and the heating chamber can provide hot air to the heat preservation passageway, the heat preservation passageway keeps warm to the heating chamber again, increase substantially the inside heat preservation effect in heating chamber.

In the present embodiment, the partition 5 includes the reinforcing plate 51 provided in two pieces; an asbestos insulation layer 52 arranged between the two reinforcing plates 51; the corrosion-resistant layer 53; the reinforcing plate is arranged at one end of the reinforcing plate far away from the asbestos heat insulation layer; an adsorption groove is formed in the corrosion-resistant layer 53, an activated carbon adsorbent is arranged in the adsorption groove 54, sealing layers 55 are arranged at the upper end and the lower end of the partition plate 5, and a sliding block 56 is further embedded in the sealing layers at the lower end of the partition plate 5.

Through the technical scheme, in the partition plate, the reinforcing plate mainly plays a role in improving the structural strength; the asbestos heat insulation layer improves the heat insulation performance of the partition plate, avoids the heat of the heating cavity from being transferred to the preheating cavity and the feeding cavity, and improves the heat insulation performance; the adsorption tank is arranged to adsorb impurities such as dust in the furnace body to a certain extent, so that the quality of the steel pipe is ensured; due to the arrangement of the sealing layer, hot gas in the heating cavity is prevented from flowing to the preheating cavity and the feeding cavity, and the heat preservation performance is improved; the friction between the partition plate and the bottom of the furnace body is reduced due to the arrangement of the sliding blocks, and meanwhile, the sealing layer at the lower end is prevented from being extruded and losing efficacy.

In this embodiment, a preheating mechanism 10 is arranged in the preheating cavity 1b, and the preheating mechanism 10 includes a gas pipe 101 communicating the heat preservation channel with the preheating cavity 1 b; the preheating pipe 102 is positioned in the preheating cavity 1b, embedded on the inner wall of the furnace body 1 and communicated with the gas conveying pipe; the air nozzle 103 is arranged on the preheating pipe, and the output end of the air nozzle faces the material bearing mechanism; the gas pipe is provided with a pressure gauge 104 and an electric control valve 105.

In this embodiment, the preheating mechanism further includes a fan 106 embedded on the inner wall of the furnace body 1; a heater 107 installed on an output end of the blower; the output end of the fan faces the preheating cavity 1 b.

According to the technical scheme, through the arrangement of the preheating mechanism, hot air flow discharged due to high pressure in the heating cavity is conveyed into the preheating pipe from the heat preservation channel through the air conveying pipe, the air nozzle blows hot air to the steel pipe to preheat the steel pipe, whether the air pressure in the heating cavity is stable or not can be detected through the observation pressure gauge, and the electric control valve can be closed to overhaul and detect faults; meanwhile, through the arrangement of the fan and the heater, hot air is formed, and when the hot air exhausted from the heating cavity is not enough for preheating, auxiliary preheating is carried out.

Example 2

As shown in fig. 9 and 10, the present embodiment is different from the above-described embodiments in that: in this embodiment, the oven door 2 is further provided with a cooling mechanism 11, and the cooling mechanism 11 includes a delivery pump 111 mounted on the oven door 2; a cold air source 112 connected to the input end of the delivery pump for providing cold air to the delivery pump; a cooling channel 113 opened on the adsorption iron plate; a cooling pipe 114 installed at an output end of the transfer pump to communicate the transfer pump with the cooling passage; and a cooling hole 115 provided on the adsorption iron plate to communicate the cooling passage with the lower end of the adsorption iron plate, wherein the cold air source may be an air cooling device in this embodiment.

In this embodiment, cooling hole and second fixed slot dislocation set, the output of cooling hole is towards the slope of second fixed slot, avoids influencing the absorption of steel pipe, guarantees that cold air blows to the steel pipe.

According to the technical scheme, through the arrangement of the cooling mechanism, when the steel pipe is discharged, the steel pipe is adsorbed by the adsorption iron plate, the conveying pump is started at the same time, cold air is conveyed into the cooling channel of the adsorption iron plate through the cooling pipe, the cold air is directly blown to the steel pipe to primarily cool the steel pipe during discharging, and the safety of subsequent material taking and processing is ensured; with cooling body and furnace gate integration setting, can reach the primary cooling to the steel pipe when getting the material, improve production efficiency.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.